QM/MM computations reveal details of the acetyl-CoA synthase catalytic center.

The "open" (Aopen) and "closed" (Aclosed) A-clusters of the acteyl-CoA synthase (ACS) enzyme from Moorella thermoacetica have been studied using a combined quantum mechanical (QM)/molecular mechanical (MM) approach. Geometry optimizations of the oxidized, one- and two-electron reduced Aopen state have been carried out for the fully solvated ACS enzyme, and the CO ligand has been modeled in the reduced models. Using a combination of both αopen and αclosed protein scaffolds and the positions of metal atoms in these structures, we have been able to piece together critical parts of the catalytic cycle of ACS. We have replaced the unidentified exogenous ligand in the crystal structure with CO using both a square planar and tetrahedral proximal Ni atom. A one-electron reduced A-cluster that is characterized by a proximal Ni atom in a tetrahedral coordination pattern observed in both the Aopen (lower occupancy proximal Ni) and Aclosed (proximal Zn atom) geometries with three cysteine thiolates and a modeled CO ligand demonstrates excellent agreement with the crystal structure atomic positions, particularly with the displacement of the side chain ring of Phe512 which appears to serve as a structural gate for ligand binding. The QM/MM optimized geometry of the A-cluster of ACS with an uncoordinated, oxidized proximal nickel atom in a square planar geometry demonstrates poor agreement with the atomic coordinates taken from the crystal structure. Based on these calculations, we conclude that the square planar proximal nickel coordination that has been captured in the Aopen structure does not correspond to the ligand-free, oxidized [Fe4S4]2+ - Nip2+ - Nid2+ state. Overall, these computations shed further light on the mechanistic details of protein conformational changes and electronic transitions involved in the ACS catalytic cycle.

Proton Transfer Pathways between Active Sites and Proximal Clusters in the Membrane-Bound [NiFe] Hydrogenase.

[NiFe] hydrogenases are enzymes that catalyze the splitting of molecular hydrogen according to the reaction H2 → 2H+ + 2e-. Most of these enzymes are inhibited even by low traces of O2. However, a special group of O2-tolerant hydrogenases exists. A member of this group is the membrane-bound [NiFe] hydrogenase from Ralstonia eutropha ( ReMBH). The ReMBH harbors an unusual iron sulfur cluster with composition 4Fe3S(6Cys) that is able to undergo structural changes triggering the flow of two electrons to the [NiFe] active site. These electrons promote oxygen reduction at the active site, preventing, in this way, aerobic inactivation of the enzyme. In the superoxidized state, the [4Fe3S] cluster binds to a hydroxyl group that originates from either molecular oxygen or water reaching the site. Both reactions, oxygen reduction to water at the [NiFe]- or [4Fe3S]-centers and oxygen evolution from water at the proximal cluster, require the delivery of protons regulated by a subtle communication mechanism between these metal centers. In this work, we sequentially apply multiscale modeling techniques as quantum mechanical/molecular mechanics methods and classical molecular dynamics simulations to investigate the role of two distinct proton transfer pathways connecting the [NiFe] active site and the [4Fe3S] proximal cluster of ReMBH in the protection mechanism against an oxygen attack. Although the "glutamate" pathway is preferred by protons migrating toward the active site to avoid inactivation by O2, the "histidine" pathway plays an essential role in delivering protons for O2 reduction at the proximal cluster. The results obtained in this work not only provide new pieces to the puzzling catalytic mechanisms governing O2-tolerant hydrogenases but also highlight the relevance of dynamics in the proper description of biochemical reactions in general.

Carbon Monoxide Dehydrogenase Reduces Cyanate to Cyanide.

The biocatalytic function of carbon monoxide dehydrogenase (CODH) has a high environmental relevance owing to its ability to reduce CO2 . Despite numerous studies on CODH over the past decades, its catalytic mechanism is not yet fully understood. In the present combined spectroscopic and theoretical study, we report first evidences for a cyanate (NCO- ) to cyanide (CN- ) reduction at the C-cluster. The adduct remains bound to the catalytic center to form the so-called CN- -inhibited state. Notably, this conversion does not occur in crystals of the Carboxydothermus hydrogenoformans CODH enzyme (CODHIICh ), as indicated by the lack of the corresponding CN- stretching mode. The transformation of NCO- , which also acts as an inhibitor of the two-electron-reduced Cred2 state of CODH, could thus mimic CO2 turnover and open new perspectives for elucidation of the detailed catalytic mechanism of CODH.

When the inhibitor tells more than the substrate: the cyanide-bound state of a carbon monoxide dehydrogenase.

Carbon monoxide dehydrogenase (CODH) is a key enzyme for reversible CO interconversion. To elucidate structural and mechanistic details of CO binding at the CODH active site (C-cluster), cyanide is frequently used as an iso-electronic substitute and inhibitor. However, previous studies revealed conflicting results on the structure of the cyanide-bound complex and the mechanism of cyanide-inhibition. To address this issue in this work, we have employed IR spectroscopy, crystallography, site directed mutagenesis, and theoretical methods to analyse the cyanide complex of the CODH from Carboxydothermus hydrogenoformans (CODHII Ch ). IR spectroscopy demonstrates that a single cyanide binds to the Ni ion. Whereas the inhibitor could be partially removed at elevated temperature, irreversible degradation of the C-cluster occurred in the presence of an excess of cyanide on the long-minute time scale, eventually leading to the formation of [Fe(CN)6]4- and [Ni(CN)4]2- complexes. Theoretical calculations based on a new high-resolution structure of the cyanide-bound CODHII Ch indicated that cyanide binding to the Ni ion occurs upon dissociation of the hydroxyl ligand from the Fe1 subsite of the C-cluster. The hydroxyl group is presumably protonated by Lys563 which, unlike to His93, does not form a hydrogen bond with the cyanide ligand. A stable deprotonated ε-amino group of Lys563 in the cyanide complex is consistent with the nearly unchanged C[triple bond, length as m-dash]N stretching in the Lys563Ala variant of CODHII Ch . These findings support the view that the proton channel connecting the solution phase with the active site displays a strict directionality, controlled by the oxidation state of the C-cluster.